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RESEARCH PRODUCT

Fine-Scale Droplet Clustering in Atmospheric Clouds: 3D Radial Distribution Function from Airborne Digital Holography

Susanne GlienkeSusanne GlienkeSusanne GlienkeMichael L. LarsenMichael L. LarsenAlexander B. KostinskiRaymond A. Shaw

subject

Physics010504 meteorology & atmospheric sciencesTurbulenceGeneral Physics and AstronomyReynolds numberParticle-laden flowsDissipationRadial distribution function01 natural sciencesComputational physicsPhysics::Fluid Dynamicssymbols.namesake0103 physical sciencessymbolsRange (statistics)Radiative transfer010306 general physicsCluster analysis0105 earth and related environmental sciences

description

The extent of droplet clustering in turbulent clouds has remained largely unquantified, and yet is of possible relevance to precipitation formation and radiative transfer. To that end, data gathered by an airborne holographic instrument are used to explore the three-dimensional spatial statistics of cloud droplet positions in homogeneous stratiform boundary-layer clouds. The three-dimensional radial distribution functions g(r) reveal unambiguous evidence of droplet clustering. Three key theoretical predictions are observed: the existence of positive correlations, onset of correlation in the turbulence dissipation range, and monotonic increase of g(r) with decreasing r. This implies that current theory captures the essential processes contributing to clustering, even at large Reynolds numbers typical of the atmosphere.

yearjournalcountryeditionlanguage
2018-11-12Physical Review Letters
https://doi.org/10.1103/physrevlett.121.204501